US6946314B2 - Method for microfabricating structures using silicon-on-insulator material - Google Patents

Method for microfabricating structures using silicon-on-insulator material Download PDF

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Publication number: US6946314B2
Authority: US; United States
Prior art keywords: layer; substrate; soi wafer; etch; wafer
Prior art date: 2001-01-02
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.): Expired - Lifetime, expires 2022-04-11

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US10/642,315

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US20040102021A1 (en

Inventor

William D. Sawyer

Jeffrey T. Borenstein

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Charles Stark Draper Laboratory Inc

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Charles Stark Draper Laboratory Inc

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2001-01-02

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2003-08-15

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2005-09-20

2002-01-02 Priority claimed from US10/038,890 external-priority patent/US6673694B2/en

2003-08-15 Priority to US10/642,315 priority Critical patent/US6946314B2/en

2003-08-15 Application filed by Charles Stark Draper Laboratory Inc filed Critical Charles Stark Draper Laboratory Inc

2004-01-14 Assigned to CHARLES STARK DRAPER LABORATORY, INC. reassignment CHARLES STARK DRAPER LABORATORY, INC. ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: BORENSTEIN, JEFFREY T., SAWYER, WILLIAM D.

2004-05-27 Publication of US20040102021A1 publication Critical patent/US20040102021A1/en

2004-07-13 Priority to US10/889,868 priority patent/US7381630B2/en

2004-08-16 Priority to PCT/US2004/026725 priority patent/WO2005017972A2/fr

2005-09-20 Publication of US6946314B2 publication Critical patent/US6946314B2/en

2005-09-20 Priority to US11/231,103 priority patent/US7335527B2/en

2005-09-20 Application granted granted Critical

2007-09-19 Priority to US11/857,720 priority patent/US7655538B2/en

2010-02-01 Priority to US12/697,713 priority patent/US8809135B2/en

2022-04-11 Adjusted expiration legal-status Critical

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- B—PERFORMING OPERATIONS; TRANSPORTING
- B81—MICROSTRUCTURAL TECHNOLOGY
- B81C—PROCESSES OR APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OR TREATMENT OF MICROSTRUCTURAL DEVICES OR SYSTEMS
- B81C1/00—Manufacture or treatment of devices or systems in or on a substrate
- B81C1/00015—Manufacture or treatment of devices or systems in or on a substrate for manufacturing microsystems
- B81C1/00134—Manufacture or treatment of devices or systems in or on a substrate for manufacturing microsystems comprising flexible or deformable structures
- B81C1/00182—Arrangements of deformable or non-deformable structures, e.g. membrane and cavity for use in a transducer
- B—PERFORMING OPERATIONS; TRANSPORTING
- B81—MICROSTRUCTURAL TECHNOLOGY
- B81C—PROCESSES OR APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OR TREATMENT OF MICROSTRUCTURAL DEVICES OR SYSTEMS
- B81C1/00—Manufacture or treatment of devices or systems in or on a substrate
- B81C1/00436—Shaping materials, i.e. techniques for structuring the substrate or the layers on the substrate
- B81C1/00555—Achieving a desired geometry, i.e. controlling etch rates, anisotropy or selectivity
- B81C1/00563—Avoid or control over-etching
- B81C1/00579—Avoid charge built-up
- B—PERFORMING OPERATIONS; TRANSPORTING
- B81—MICROSTRUCTURAL TECHNOLOGY
- B81C—PROCESSES OR APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OR TREATMENT OF MICROSTRUCTURAL DEVICES OR SYSTEMS
- B81C3/00—Assembling of devices or systems from individually processed components
- B81C3/001—Bonding of two components
- B—PERFORMING OPERATIONS; TRANSPORTING
- B81—MICROSTRUCTURAL TECHNOLOGY
- B81C—PROCESSES OR APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OR TREATMENT OF MICROSTRUCTURAL DEVICES OR SYSTEMS
- B81C2201/00—Manufacture or treatment of microstructural devices or systems
- B81C2201/01—Manufacture or treatment of microstructural devices or systems in or on a substrate
- B81C2201/0174—Manufacture or treatment of microstructural devices or systems in or on a substrate for making multi-layered devices, film deposition or growing
- B81C2201/0191—Transfer of a layer from a carrier wafer to a device wafer

Definitions

the invention relates generally to MicroElectroMechanical Systems (MEMS), in particular, to methods for microfabricating MEMS devices on Silicon-On-Insulator (SOI) wafers.
MEMS MicroElectroMechanical Systems
SOI Silicon-On-Insulator
MEMS MicroElectroMechanical Systems
SOI Silicon-On-Insulator
Prior methods for fabricating MEMS devices using a bonded handle wafer include the dissolved wafer process, in which silicon is bonded to glass and the silicon is dissolved away to reveal an etch-stop layer.
This etch-stop layer typically comprises a heavily-doped boron-diffused or boron-doped epitaxial layer, but may also consist of a SiGe alloy layer.
methods that involve the use of a heavily-boron-doped etch stop suffer in several respects, including poor process control, high defect densities, limitations on ultimate thickness of devices, and incompatibility with microelectronic device integration. Insertion of a SiGe alloy layer resolves several of these limitations, but that method suffers from relatively low deposition rates and material property issues. SOI micromachining has demonstrated that a limited number of device types may be successfully constructed, but the build quality is lacking and many design constraints exist.
the principal constraint involves the problems encountered when performing deep reactive-ion-etching (RIE) of the silicon device layer on top of the oxide interlayer; the RIE process tends to attack the underside of the silicon device layer due to charging of the dielectric layer. Steps have been taken by RIE equipment vendors to resolve this problem, and such methods have mitigated these etch effects.
RIE deep reactive-ion-etching
the invention provides a general fabrication method for producing MicroElectroMechanical Systems (MEMS) and related devices using Silicon-On-Insulator (SOI) material.
the method includes providing a Silicon-On-Insulator (SOI) wafer, which has (i) a handle layer, (ii) a dielectric layer, which preferably is a SiO 2 layer, and (iii) a device layer, wherein a mesa etch has been made on the device layer, providing a substrate (such as glass or silicon), where a pattern has been etched onto the substrate, bonding the SOI wafer to the substrate, whereby the etched device layer faces the patterned surface of the substrate, removing the handle layer of the SOI wafer, removing the dielectric layer of the SOI wafer, and etching the device layer of the SOI wafer to define the MEMS device.
SOI Silicon-On-Insulator
BESOI Bonded and Etch Back Silicon-On-Insulator
the substrate is etched with a predetermined pattern, and a metal layer is deposited and metal runners are formed on the patterned substrate.
a second SOI wafer is provided to be used as a substrate.
the highly doped device layer of the second SOI wafer is etched and patterned to form electrically conductive Silicon lines, which take the place of metal lines.
the patterned device layer of the first SOI wafer is then bonded to the patterned device layer of the second SOI wafer.
the handle layer and the dielectric layer of the first SOI wafer are removed, and the device layer of the first SOI wafer is further etched to define the MEMS device.
the method of the invention provides (1) the ability to micromachine devices on SOI substrates without design constraints for structure spacing; etch gaps, oxide thickness or other features, and (2) a flexibility for handle wafer type and bonding process.
This invention also addresses several of the previous barriers to general use of SOI material for MEMS and associated applications.
the invention enables the use of SOI wafers to build a wide array of device types that were previously only feasible using standard boron etch stop technology.
the method allows for the use of RIE etch technology to produce high-quality structures on devices bonded everywhere to a silicon dioxide buried layer.
the invention relieves all of the design constraints previously required for SOI structures, including the spacing between structural elements, spacing between the device and the edge of the die, and special requirements for atmospheric conditions during bonding of SOI wafers to handle wafers.
the invention also provides intermediate structures in the general fabrication method.
the intermediate structures are mechanically stable, though they contain internal cavities formed by the etched SOI wafer and the substrate.
the cavities can be of various shapes and sizes.
the intermediate structure have an access port in the substrate.
the intermediate structures can be made using components with arbitrary thickness and arbitrary doping.
the invention further provides a method for making an accelerometer, using the methods of the invention.
the substrate is provided with access ports to equalize the pressure between the internal cavities and outside of the wafer sandwich.
the process of bonding the SOI wafer and the substrate is performed at a pressure less than atmospheric pressure.
some gas can be present in the cavities formed between the Si and the substrate, but the gas pressure is not great enough to cause devices to explode during a subsequent potassium hydroxide (KOH) etch to remove the handle layer. This step avoids the need for drilling holes in the substrate.
KOH potassium hydroxide
FIG. 1 is a schematic side drawing showing a prior art single depth microfabrication process
FIG. 2 is a schematic side drawing showing the process steps prior to substrate bonding
FIG. 3 is a schematic side drawing showing the process steps of the invention for glass substrate fabrication
FIG. 4 is a schematic side drawing showing bonding, wafer thinning and oxide dielectric removal
FIG. 5 is a schematic side drawing showing the baseline BESOI process sequence
FIG. 6A is a schematic view of a prior art device structure showing that the underside of the Si beam is etched
FIG. 6B is a schematic view of a device structure showing that the Si beam is protected from underside etching
FIG. 7 is a schematic side view showing the baseline BESOI process sequence, wherein an SOI wafer is used as a substrate;
FIG. 8 is a set of electron micrographs showing (a) epitaxial comb fingers and (b) the baseline BESOI comb fingers;
FIG. 9 is an electron micrograph showing the phenomenon of RIE lag, where narrow trenches etch more slowly.
a standard SOI wafer 10 is provided, which is shown in FIG. 2 , and which comprises a handle layer 12 , a dielectric layer 14 usually consisting of silicon dioxide, and a device layer 16 (see, FIG. 2 a ).
Such wafers are commercially available from many sources, and are fabricated using wafer bonding, SIMOX technology, Smart-Cut methods, or other processes. Wafers can also be obtained from a large number of vendors of standard semiconductor material, and are sawn and polished to provide precise dimensions, uniform crystallographic orientation, and highly polished, optically flat surfaces.
the handle wafer is of sufficient thickness for handling purposes, without other requirements.
the dielectric layer is thick enough for electrical isolation and effective etch-stop action, yet thin enough so as not to cause severe bowing of the SOI wafer.
the device layer parameters are important, as they will translate directly into properties of the resulting structure. Thickness of the device layer determines the device thickness (including any gap that may be machined between the device and the substrate). Electrical resistivity, carbon and oxygen content, growth technique, crystallographic orientation and other wafer parameters are selected based on the properties requited of the end product. Surface finish should be highly polished. The interface between the dielectric and device layers should not have voids.
FIG. 2 shows the primary steps involved in preparing the SOI wafer for bonding to a substrate wafer.
mesas are preserved in the device layer and the background is etched back, so that the final structure, when bonded to a substrate, has regions which are directly bonded (the mesas) and regions suspended above the planar surface of the substrate (i.e., everywhere else on the wafer; see, FIG. 2 b ).
the mesa etch may be performed using KOH or other etchants.
the wafer is cleaned and patterned for the “structural” etch (see, FIG. 2 c ).
the structural etch is a Deep Reactive Ion Etch (DRIE) process, in which high aspect ratios may be desired (Ayon A A et al., Mat. Res. Soc. Symp. Proc. 546: 51 (1999); Ayon A A et al., J. Vac. Sci. Tech. B 18: 1412 (2000)). Since the process etches straight down to the dielectric layer, which is bonded everywhere to the device layer, techniques designed to prevent plasma etching problems at the dielectric—device interface become very effective.
DRIE Deep Reactive Ion Etch
micromachining of silicon can be observed by the use of epifluorescence microscopy or by the use of metallurgic microscope. Alternatively, the micromachining can be observed by an electron microscope, such as a scanning electron microscope (SEM).
SEM scanning electron microscope
the SOI wafer that has been patterned and etched for both the mesa and structural layers is then bonded to a substrate.
the substrate can be glass, silicon or other equivalently workable material.
the fabrication steps for a glass substrate 20 are those outlined in FIG. 3 .
the glass wafer 20 is cleaned and patterned for the electrode pattern.
the electrode pattern is composed of multilevel metallization.
the glass wafer 20 is then recess-etched, and, without removing the photoresist, a blanket sputter of the multilevel metallization is performed. Finally, the wafer undergoes “lift-off”, where metal not applied directly to the substrate is removed.
access ports 22 in the glass substrate 20 are formed in the glass substrate 20 .
the advantage for this process step is described below, where the substrate wafer is bonded to the processed SOI wafer.
These access ports 22 may be etched, or more preferably, mechanically or ultrasonically drilled through the glass substrate. The spacing of these holes is determined by the die size and by the presence and distribution of bonded seals between the SOI wafer and the substrate. Since the purpose of the access ports is to equalize the pressure between the internal cavities and outside of the wafer sandwich, at least one such port must be positioned within each region sealed by bonding. Typically, these regions coincide with the die size, so that each device is isolated from all others by a bonded structure known as a seal ring.
the quantity of gas inside the cavity is fixed when the bond is formed.
the pressure inside the cavity p nRT/V, where n is the number of moles of gas present (fixed), V is the volume of the cavity (fixed), R is the universal gas constant, and T is the temperature.
the pressure inside the cavity at room temperature is (293/573) atm ⁇ 0.5 atm. Therefore, in room ambient, the cavity is in an underpressure situation, while in a vacuum chamber, it is at an overpressure situation.
the pressure inside the cavity can be different from that of the outside world. Analysis indicates that such a pressure differential will lead to fracture of the oxide interlayer.
Use of an access port resolves the problem of the pressure differential.
the handle layer of the SOI wafer must be removed. Without an access port, this material may be removed in a wet chemical etch or by a dry plasma etch. With the access port present, only the dry process is used. For example, a RIE tool may be used to remove the handle silicon layer.
RIE process tool One required feature of RIE process tool is that it enables the plasma removal to occur with equalized pressure across the oxide dielectric. The other required feature is that plasma gases cannot gain access to the cavity through the port; otherwise, attack of structural layers would ensue.
the final step in the process is removal of the oxide dielectric.
removal of the dielectric layer must be performed using a dry plasma etch process, so as not to attack the bulk glass and metallization on the topside of the device. Once the dielectric has been removed, the final structure is produced.
This structure is expected to have excellent build quality, as it benefits from several significant process improvements: (1) high material quality through use of virgin SOI material rather than highly doped layers; (2) very high fidelity DRIE processing, due to fully bonded device and oxide dielectric layer during the etch process, and newly-developed vendor equipment and processes designed specifically for these applications; (3) high quality access port holes, drilled using ultrasonic methods which produce smooth walls without stress concentrations; (4) complete flexibility in wafer bonding process, without concern for ambient conditions and resulting pressure differentials; and (5) dry plasma etch wafer thinning process, which allows for pressure equalization across oxide dielectric, eliminating possible exposure of device layer to etchant.
One group of former methods for fabricating micromachined structures in silicon involves the use of an etch-stop such as heavily-doped boron layers or SiGe layers.
the method of the invention has several distinct advantages over that family of techniques, including increased process flexibility without the requirement for heavy doping, a higher-quality silicon device layer, and improved process control.
Alternate methods for the invention include, but are not limited to (1) the use of silicon or other crystalline substrates rather than a glass substrate, (2) anodic bonding using a thin layer of sputtered PYREX® rather than a full glass wafer, (3) fusion bonding rather than anodic bonding of the lower handle wafer, etching or other processes rather than ultrasonic drilling, (4) alternate means for removing the SOI handle layer, and (5) the use of materials other than silicon and silicon dioxide for the device layer and etch-stop layer, respectively. Wafers made from PYREX®, other borosilicate glass, or other glasses can also be procured and inserted into micromachining processes, with alternative processes used to etch the glassy materials. See, published PCT patent application WO 00/66036; Kaihara et al., Tissue Eng 6(2): 105-17 (April 2000).
Plasma etching provides the ability to control the width of etched features as the depth of the channel is increased. Wet chemical processes typically widen the trench substantially as the depth is increased, leading to a severe limitation on the packing density of features (Fruebauf J & Hannemann B, Sensors and Actuators 79: 55 (2000)). Several different plasma etching technologies have been recently developed. One of the available etch processes is know as the Bosch process.
the process of bonding the SOI wafer and the substrate is performed at a predetermined pressure less than atmospheric pressure, for example, 200 mTorr.
a predetermined pressure less than atmospheric pressure, for example, 200 mTorr.
KOH potassium hydroxide
the handle layer of the SOI wafer is removed by a relatively fast wet etch, for example, using potassium hydroxide (KOH).
KOH potassium hydroxide
the fast etching of the handle layer is terminated at a predetermined distance, e.g., about 10 ⁇ m, from the SiO 2 layer.
Removal of the rest of the handle layer is preferably done by a relatively slow etch, for example, using tetramethyl ammonium hydroxide (TMAH).
TMAH tetramethyl ammonium hydroxide
the etch of the rest of the handle layer is preferably performed slowly and stops well at the SiO 2 layer.
This etch can also be performed using XeF 2 , which is a non-ionized gas that has a Si:SiO 2 etch ration as high as 10,000:1.
the next step in the process is removal of the SiO 2 layer.
removal of the SiO 2 layer is preferably performed using an RIE dry plasma etch process, so as not to attack the bulk glass and metallization on the topside of the device.
the SiO 2 can be removed in an RIE tool using a recipe designed for SiO 2 etching.
This process can be performed at desired gas pressure, such as 200 mTorr, which is substantially the same as the pressure at which the bonding of the SOI wafer and the substrate is performed.
desired gas pressure such as 200 mTorr
the previously described method requires the mesa etching and structural etching to be performed before the SOI wafer is bonded to a substrate wafer.
the handle layer part of the SOI wafer is removed using a wet etch.
the wet etch which removes the handle layer must stop on the thin SiO 2 layer. If the etch does not completely stop at the SiO 2 layer, the etch chemicals would penetrate the device and destroy it.
the structural etching which is performed before the SOI wafer is bonded to the substrate, defines cavities in the device layer. In these cavities, there is no Si underneath the SiO 2 to mechanically support the SiO 2 layer. During the etching process for removing the handle layer, the etch chemicals may penetrate the SiO 2 layer, which has no Si support, and destroy the device under the SiO 2 layer.
FIG. 5 illustrates an alternative fabrication method, which is called Bonded and Etch Back Silicon-On-Insulator (BESOI).
BESOI Bonded and Etch Back Silicon-On-Insulator
the structural etching is performed after the SOI wafer is bonded to the substrate, and after the handle layer and SiO 2 layer are removed.
the SiO 2 layer is supported by the underlying Si across the complete surface of the SOI wafer.
the SiO 2 layer functions as a good etch stop, and no etch chemicals penetrate the device region when the handle layer of the SOI wafer is removed.
the BESOI method begins with a standard SOI wafer 10 , similar to that used in the previously described SOI processes.
the SOI wafer is cleaned and patterned for the mesa etch.
the mesa etch may be preformed by several methods, for example, using KOH.
the glass substrate fabrication steps are similar to the previously described methods, which are outlined in FIG. 3 .
the glass substrate may be provided with access ports to equalize the pressure between the internal cavities and outside of the wafer sandwich.
the SOI and glass wafers are anodically bonded, with the device side of the SOI wafer bonded to the metallized side of the glass substrate.
the bonding process also can be performed under a predetermined pressure, which is less than atmosphere pressure, as described above.
the handle layer of the SOI wafer is preferably removed by a relatively fast wet etch, for example, using potassium hydroxide (KOH).
KOH potassium hydroxide
the etching of the handle layer is stoped at a predetermined distance, e.g., about 10 ⁇ m, from the SiO 2 layer.
Removal of the rest of the handle layer is preferably done by a relatively slow etch, for example, using tetramethyl ammonium hydroxide (TMAH).
TMAH tetramethyl ammonium hydroxide
the etch of the rest Si is preferably performed slowly and stops well on the SiO 2 layer. This etch can also be performed using XeF 2 , which is a non-ionized gas that has a Si:SiO 2 etch ratio as high as 10,000:1.
the next step in the process is removal of the SiO 2 layer.
removal of the SiO 2 layer is preferably performed using an RIE dry plasma etch process.
the SiO 2 can be removed in an RIE tool using a conventional recipe designed for SiO 2 etching.
the device layer is revealed and ready for structural etching.
the device layer is then etched to define the device preferably by Inductively Coupled Plasma (ICP), using a Surface Technology Systems plc (STS) machine, which prevents charge build-up causing “footing”.
ICP Inductively Coupled Plasma
STS Surface Technology Systems plc
the structural etching process may etch straight down to the glass substrate.
the above described prior art process step is replaced with a new process step, which avoids damage of the underside of the nearby Si of the device.
the glass substrate is covered with a substantially uniform metal layer, which, during the etch, prevents charge build-up, as shown in FIG. 6 B.
gaps in metal layer are necessary to keep metal regions or lines separate. These gaps are preferably placed other than under an operable element which is to be formed by etching the device layer, or placed in areas where damage to the device will not affect the performance of the device. For example, as shown in FIG. 6B , the area directly underneath the drive or sense fingers of a MEMS device is covered by metal, and the gap between the Si and the metal is placed other than under the finger.
the ICP etch is performed after the SOI wafer is bonded to the glass substrate.
the silicon which is to be removed, is preferably not bonded to the glass, because it is very difficult for the ICP etch to remove Si, which has been bonded to the glass.
a few microns of the surface of the silicon are preferably removed before the SOI wafer is bonded to the glass wafer. The removal of the silicon can be done in the mesa etch, as shown in FIG. 2 .
FIG. 7 illustrates another alternative BESOI method of the invention, which uses highly doped silicon or other crystalline substrates rather than a glass substrate.
a second SOI wafer is provided to be used as the substrate.
the device layer of the second SOI wafer is etched straight down to the dielectric layer to form highly doped (and thus electrically conductive) “Si runners”, which can be used as electrically conductive lines and contacts.
Si runners are formed, the first etched SOI wafer is bonded to the second substrate SOI wafer.
the substrate SOI wafer can be used in all previously described methods to replace the glass substrate.
the invention is also useful in the manufacture of an accelerometer.
An accelerometer pattern is etched into the SOI wafer.
Guidance for making an accelerometer is provided in U.S. Pat. No. 6,269,696, “Temperature compensated oscillating accelerometer with force multiplier”, issued Aug. 7, 2001 to Weinverg et al., incorporated herein by reference.
the driving force for using SOI material instead of epitaxial material to build the accelerometer is the greatly enhanced process flexibility afforded by the SOI process.
the best crystallographic quality is expected to produce the best devices.
Device layers on SOI wafers can be of any doping level, type, crystallographic quality, etc.
epitaxial layers must be heavily-doped with boron. High doping concentrations of B are associated with etch pits, extended defects, curvature and strain, all undesirable features for strategic devices.
boost requirements require that the accelerometer be radiation hardened against fast neutrons, thermal neutrons and gamma radiation. Boron doping reduces hardness against thermal neutrons; therefore SOI material is preferred. More importantly, the glass substrate, whether PYREX® or Hoya SD-2, exhibits compaction under fast neutron and gamma irradiation [C. Allred, Master's Thesis, MIT Materials Science and Engineering Department, August 2000. Fabrication of an accelerometer built from SiGeB epitaxial material would be difficult to impossible with a silicon-on-silicon process, but would be very compatible with the use of SOI material for the device layer.
Difficulties with this process are mainly associated with the final step in the process, in which the structural element is etched into the SOI device layer using the (Inductively Coupled Plasma) ICP etching process.
Etching of the structural element in epitaxial processes occurs prior to bonding to the glass substrate. Therefore, the ICP etch must penetrate below the line of the SiGeB etch stop layer, so that subsequent backside wafer dissolution results in full release.
RIE lag a phenomenon known as RIE lag, shown in FIG. 8 , causes wide features to etch deeper than narrow features. However, this over-etch causes no serious harm, since wide features simply penetrates more deeply into the silicon wafer.
New ICP etch technology is specifically aimed at reducing notching and underside attack.
the new technology is most effective when silicon is directly bonded to the non-etching substrate, such as glass or oxide.
Alternatives attempted to date principally address the notching problem, and entail ICP etching down to the buried oxide layer prior to anodic bonding.
ICP etch is conducted using newly available SOI etch technology
a pressure relief hole is inserted in the glass to eliminate pressure differentials during wafer thinning
Wafer thinning is accomplished using a dry plasma process rather than a wet etch
the die layout is adjusted to minimize the spacing between anchored features (without affecting the actual accelerometer design.)
a standard SOI wafer is provided, which is similar to that used in both the baseline and prototype alternative SOI processes.
the SOI wafer is cleaned and patterned for the mesa etch.
the mesa etch may be performed using KOH or other etchants. This represents yet-another advantage of the SOI process over its predecessors.
the wafer is cleaned and patterned for the structural etch. Since the process etches straight down to the dielectric layer, which is bonded everywhere to the device layer, technology designed to prevent plasma etching problems at the dielectric—device interface becomes very effective.
the SOI wafer which has been patterned and etched through both the mesa and structural layers, is then bonded to a glass substrate.
the glass substrate fabrication steps are outlined in FIG. 3 .
the glass wafer is cleaned and patterned for the electrode pattern.
the electrode pattern is composed of multilevel metallization.
the glass wafer is then recess-etched, and, without removing the photoresist, a blanket sputter of the multilevel metallization is performed. Finally, the wafer undergoes “lift-off”, where metal not applied directly to the substrate is removed.
access ports are evident, as the substrate wafer is bonded to the processed SOI wafer.
These access ports may be etched, or more preferably, mechanically or ultrasonically drilled through the glass. The spacing of these holes is determined by the die size and by the presence and distribution of bonded seals between the SOI wafer and the substrate. Since the purpose of the access ports is to equalize the pressure between the internal cavities and outside of the wafer sandwich, at least one such port must be positioned within each region sealed by bonding. Typically, these regions coincide with the die size, so that each device is isolated from all others by a bonded structure known as a seal ring.
the handle layer of the SOI wafer must be removed. Without an access port, this material may be removed in a wet chemical etch or by a dry plasma etch. With the access port present, only the dry process may be used. For the present example, a RIE reactor may be used to remove the handle silicon layer.
RIE process tool One required feature of RIE process tool is that it enables the plasma removal to occur with equalized pressure across the oxide dielectric. The other required feature is that plasma gases cannot gain access to the cavity through the port; otherwise, attack of structural layers would ensue.
the final step in the process is removal of the oxide dielectric.
removal of the dielectric layer must be performed using a dry plasma etch process, so as not to attack the bulk glass and metallization on the topside of the device. Once the dielectric has been removed, the final structure is revealed. Excellent build quality is expected, based upon the use of the new ICP SOI etching technology and pressure equalization during thinning.

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US10/642,315 2001-01-02 2003-08-15 Method for microfabricating structures using silicon-on-insulator material Expired - Lifetime US6946314B2 (en)

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Application Number	Priority Date	Filing Date	Title
US10/642,315 US6946314B2 (en)	2001-01-02	2003-08-15	Method for microfabricating structures using silicon-on-insulator material
US10/889,868 US7381630B2 (en)	2001-01-02	2004-07-13	Method for integrating MEMS device and interposer
PCT/US2004/026725 WO2005017972A2 (fr)	2003-08-15	2004-08-16	Procede de microfabrication de structures au moyen de materiau de silicium sur isolant
US11/231,103 US7335527B2 (en)	2001-01-02	2005-09-20	Method for microfabricating structures using silicon-on-insulator material
US11/857,720 US7655538B2 (en)	2001-01-02	2007-09-19	MEMS device and interposer and method for integrating MEMS device and interposer
US12/697,713 US8809135B2 (en)	2001-01-02	2010-02-01	MEMS device and interposer and method for integrating MEMS device and interposer

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US25928201P	2001-01-02	2001-01-02
US10/038,890 US6673694B2 (en)	2001-01-02	2002-01-02	Method for microfabricating structures using silicon-on-insulator material
US40379602P	2002-08-15	2002-08-15
US10/642,315 US6946314B2 (en)	2001-01-02	2003-08-15	Method for microfabricating structures using silicon-on-insulator material

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US11/231,103 Division US7335527B2 (en)	2001-01-02	2005-09-20	Method for microfabricating structures using silicon-on-insulator material

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US20040102021A1 (en)	2004-05-27
US20060014358A1 (en)	2006-01-19
US7335527B2 (en)	2008-02-26
WO2005017972A3 (fr)	2005-09-09

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